Dissociation and preservation of preantral follicles and immature oocytes from female dasyurid marsupials
N. A. Czarny A B , M. S. Harris A and J. C. Rodger AA School of Environmental and Life Sciences, The University of Newcastle, Callaghan, NSW 2308, Australia.
B Corresponding author. Email: natasha.czarny@studentmail.newcastle.edu.au
Reproduction, Fertility and Development 21(5) 640-648 https://doi.org/10.1071/RD08303
Submitted: 22 December 2008 Accepted: 5 March 2009 Published: 18 May 2009
Abstract
The mammalian ovary contains numerous immature preantral follicles that are not dependent on endocrine support, unlike the more mature hormone-dependant antral follicles. Preantral follicles can be enzymatically dissociated to yield immature oocytes that survive sub-zero preservation better as they lack a temperature-sensitive meiotic spindle. These techniques are highly applicable to gamete banking, which is an urgent requirement for Australian carnivorous marsupials as several species have rapidly declining populations and risk extinction. The present study developed protocols for the transport, dissociation, preservation and culture of granulosa cell-oocyte complexes (GOC) from the ovaries of dasyurid marsupials. High viability of GOC following enzymatic dissociation is reported and it was demonstrated that GOC are of significantly better quality following refrigerated storage for 24 h compared with storage at room temperature. Oocytes from primary follicles were not damaged by cold shock or the toxicity of vitrification media and following vitrification in liquid nitrogen 69.42 ± 2.44% of oocytes were viable. However, the surrounding granulosa cells demonstrated significant damage post-thaw. These granulosa cells proliferated during a 48-h culture period resulting in significant improvements in GOC quality. The present study is a valuable step towards cryostorage of dasyurid gametes and represents fundamentally important methods by which we can contribute to the conservation of Australia’s native predators.
Additional Keyword: vitrification.
Acknowledgements
We thank Australian Ecosystems Foundation and Remabi Park for the supply of eastern quolls; Woolworths Ltd Jesmond store generously donated quoll food. We appreciate the efforts of staff from Territory Wildlife Park, the Tasmanian Government and Tamara Keeley for collection of northern quoll and Tasmanian devil tissues. We also thank Simon Forsyth for assistance and Ellie Hayward at Charles Darwin University for access to laboratories whilst in the Northern Territory. Kim Colyvas at the University of Newcastle provided statistical advice. This research was supported by the University of Newcastle and N.C. was the recipient of a University of Newcastle Research Scholarship and the Barker PhD Award.
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